JP2010183922A - Flour paste - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide acidic flour paste having favorable flavor, smooth palate feeling and good meltability in the mouth. <P>SOLUTION: The flour paste which achieves these purposes is produced by adding acidic and soluble soybean protein to starchy raw material. The addition of the acidic and soluble soybean protein preferably accounts for 50 wt.% based on the starchy raw material. The flour paste preferably has pH 3.5 to 5.9. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a starchy food material or a starchy food.

  A baked confectionery made from wheat flour, rice flour, or starch, the main ingredient of the body being heated, such as roasting, baked confectionery obtained by fermenting the kneaded dough and baking, and the same kneaded dough Noodles such as noodles and Chinese noodles obtained by steaming rice are examples of starchy foods that are popular all over the world. As one of the methods for improving the texture of such starchy foods, it is known to add a protein material. However, conventionally used protein materials have poor dispersibility in the dough, and are sufficient. It has been suggested that the average particle size of the protein material to be used is significantly reduced by airflow pulverization or freeze pulverization (Patent Document 1). Therefore, the goal of improving the quality of starchy foods is that the flavor of the confectionery or bread is not impaired, the steamed food has a fluffy texture, good touch and melts, and the baked confectionery has a solid texture. However, the inside is soft and melts in the mouth, and the cakes are moist with a fluffy texture without being crispy, and in bread etc. the surface is crispy and crispy, soft and meltable It was to provide a confectionery or bread that is excellent in appearance such as voluminous feel and that does not age easily during storage.

  In addition, in the production of fried foods, where starchy food materials are used as food materials (batters), the problem of maintaining a crispy or crispy texture immediately after frying as long as possible, or freezing -Even when cooked in a microwave oven after refrigeration, protein materials are added as a problem because it can taste the same crispy or crispy texture as that immediately after manufacture (for example, patents) Reference 2).

  In addition, spring rolls and dumpling skins also have a problem of maintaining a crispy texture without losing the crispy texture when left for a long time after fried or baked, and soy protein is also being considered for use. (Patent Document 3).

  On the other hand, when soybean protein is used for noodles, the firmness becomes strong, but the lack of flexibility tends to deteriorate the texture.

  There are many other attempts to use soy protein to improve the quality of starchy foods, but many of these proposals indicate that the use of soy protein has a certain improvement effect, and there is still room for improvement. Indicates that there is.

  One of the difficulties often encountered with soy protein in starchy foods, especially in bakery products using wheat flour, is the loss of product lump volume and poor appearance, and the soy protein is increasingly refined as the degree of purification increases. There is a tendency for the loss of lump volume and poor appearance to increase, and when using low-purity soy protein, there is a drawback that it tends to give a soy odor. There has been proposed a method of mixing with a water-based system and using it as a component of flour dough (Patent Document 4). In addition, as the amount of soy protein used is increased when mixing soy protein with flour dough, the viscosity of the dough increases, and there is a problem that workability is reduced in forming flour dough.

  On the other hand, soybean protein generally has an isoelectric point near pH 4.5, is insoluble in the acidic region in the vicinity, and has a problem that it does not function sufficiently when insoluble. Although the method of improving is proposed and it is tried to use in an acidic region (patent document 5 and patent document 6), the use of such soybean protein is mainly for acidic foods, and is non-acidic. None of the foods were intended, and the overall improvement was not a starchy food.

JP 2002-171897 JP 2002-58437 A JP 2002-65192 A JP 59-118034 A Japanese Patent Publication No.53-19669 WO 02/067670 A1

  The present inventor unexpectedly improved the texture when using an acidic and soluble soybean protein having a pH of 4.5 or less in the production of the starchy food that is not an acidic food. (Although it varies slightly depending on the water activity, in the case of a baked food with a high or intermediate moisture of AW of about 0.5 or more, it has a fluffy texture, good touch and mouth melt, and on the other hand a low water activity baked confectionery For toasted bread, the texture is light and crunchy, and for udon and Chinese noodles, it has a moderate elasticity and a flexible texture. It has been found that (loss of product lump volume, poor appearance) and ease of use (decrease in workability) are alleviated, and the present invention has been completed.

That is, this invention
(1) A flour paste obtained by adding an acidic soluble soybean protein to a starchy raw material.
(2) The flour paste according to (1), wherein the starchy raw material is mainly composed of starchy flour, starch obtained from the starch, processed starch, or a mixture thereof.
(3) The flour paste according to (1), wherein the acid-soluble soybean protein is 50% by weight or less based on the starchy raw material.
(4) The flour paste according to (1), wherein the pH of the flour paste is 3.5 to 5.9.

  According to the present invention, the use of a small amount of soybean protein has the effect of improving the texture of starchy foods and improving the workability in the process of producing starchy foods, particularly from mixing to molding. And the difficulty (loss of product lump volume, bad appearance) and usability (decrease in workability) when using soy protein in a large amount can be well reduced.

  The starchy raw material used in the present invention may be a known one, and starchy flours such as wheat, rice, corn, potato, tapioca, rice, cassava, sweet potato, wheat starch, corn starch, potato starch, tapioca obtained therefrom. Cereal starches such as starch, rice starch, cassava starch, and sweet potato starch, and chemical or physical treatments such as acetate esterification, phosphoric acid crosslinking, hydroxypropyl etherification, octenyl succinate esterification, and alphatization of the grain starch Dextrins such as indigestible dextrin, branched dextrin, etc. can be exemplified, including processed starch, and dextrin, and mixtures thereof can also be used.

  Also, when the starchy raw material contains gluten such as wheat flour, especially when the starchy raw material contains 30% by weight or more of wheat flour, or the same amount of gluten as used together with starchy raw materials other than wheat flour such as rice flour If this is the case, it is difficult to use a large amount of normal soybean protein in combination with the viscosity of gluten, that is, loss of product lump volume, poor appearance, and difficulty in use due to increased viscosity (decrease in workability). Etc. can be reduced well.

  The acid-soluble soybean protein used in the present invention has a solubility at pH 4.0 of 60% or more, preferably 65% or more, more preferably 80% or more, and still more preferably 90% or more. The partial hydrolyzate may be used.

* Solution rate (%) is a measure of solubilization of protein in a solvent. If necessary, a solution in which protein powder is dispersed in water so that the protein content is 5.0% by weight is sufficiently stirred. After adjusting the pH, the ratio of the supernatant protein centrifuged at 10,000 G × 5 minutes to the total protein is measured by a protein quantification method such as Kjeldahl method or Raleigh method.

  There are various methods for producing acidic soluble soy protein, but a solution containing soy protein (soy milk, defatted soy milk, aqueous solution of separated soy protein, etc.) is more acidic than the pH of the isoelectric point of the protein, A method of heat treatment at a temperature exceeding 100 ° C. is preferred. The heated product is then dried to obtain an acidic soluble soybean protein powder that is acidic by itself and has a higher dissolution rate than pH 4.5.

  Among them, an acid-soluble soybean protein obtained by a production method disclosed in WO 02/67690 is most preferable because it has high solubility at pH 4.5 or lower. In the solution containing soybean protein, (A) a process of removing or inactivating the polyanionic substance derived from the raw material protein in the solution, for example, decomposing and removing phytic acid in soybean with phytase or the like Treatment, or (B) a treatment of adding a polycationic substance to the solution, for example, a treatment of adding chitosan, and after the treatment of either (A) or (B) or both, The protein solution is heat-treated at a temperature exceeding 100 ° C. in the acidic region from the pH of the isoelectric point, and usually dried thereafter.

  The acidic soluble soy protein in the present invention may be a partially decomposed product, and other nitrogen compounds, such as acidic and poorly soluble proteins, protein hydrolysates, peptides, amino acids and the like. Does not interfere with inclusion in starchy food materials or starchy foods.

  Acid-soluble soybean protein can be used over a wide range of 0.05 to 50% by weight with respect to the starchy raw material, but also in the conventional small amount range of 3% or less or 2.5% or less. As compared with the case of using soy protein in a larger amount than this, a sufficiently excellent effect can be exhibited. The upper limit value varies depending on the purpose, and is preferably 5% by weight or less for expanded products such as bread and cakes. Alternatively, in a product in which the amount of starchy raw material such as flour paste used is as low as 10% by weight or less in the system, addition of 50% by weight or less of acidic soluble soybean protein per starchy raw material is preferable.

  This invention does not require the starchy food material or starchy food to be acidic at all because an acid-soluble soybean protein is used. Rather, it is a starchy food having a hydrous pH of 4.5 to 9. It can be suitably used for raw materials or starchy foods, and is most usually in the range of pH 5 to 7.5. However, for Chinese noodles using brine, pH 7.5-9 is preferred.

  That is, starchy foods can be biscuits / cookies, cakes, breads, shoe puffs, dressed fried foods, or noodles such as snack foods, udon, and Chinese noodles, and they definitely belong to these categories. Other baked confectionery and bakery products such as donuts, hot cakes, American dogs, steamed products such as steamed bread, buns, takoyaki, okonomiyaki, etc. are also included. In addition, the starchy food material, which is a material of these starchy foods, can be powdery, doughy, pasty, battery, or the latter three components, premix, mixed powder, dusting , Batter powder, spring roll skin, dumpling skin, flour paste, etc.

  In the starchy food material or starchy food, known materials, additives, and aqueous materials can be used in a known range as the target material or the raw material of the target food, and processed by a known method. Can do. For example, the fats and oils can be exemplified by animal and vegetable fats and oils, fractionated, hardened or transesterified oils, butter, margarine and shortening, oil-in-water creams, and the emulsifiers are lecithin, glycerin fatty acid esters (glycerin fatty acid monoesters, glycerin fatty acids). Examples include diesters, glycerin fatty acid organic acid esters), polyglycerin fatty acid esters, and sucrose fatty acid esters, and so-called emulsified oils and fats with an emulsifier according to the purpose are also available.

  As a thickener, stabilizer, or dietary fiber, guar gum, locust bean gum, glucomannan, tamarind seed gum, pullulan, polydextrose, indigestible dextrin, guar gum degradation product, water-soluble soybean polysaccharide, psyllium seed gum, Examples include gum arabic, propylene glycol alginate, and agar. Ammonium hydrogen carbonate, sodium hydrogen carbonate, and baking powder containing them can be used as the swelling agent and the rinsing. Aqueous raw material water may be derived from milk, alcoholic beverages, eggs and the like in addition to the water itself.

  The method of adding the acidic soluble soybean protein to the starchy raw material is not limited to mixing directly with the starchy raw material, and there is no particular problem as long as the acidic soluble soybean protein can be dispersed in the system. For example, powders other than starchy raw materials, water-in-oil emulsions, oils and fats previously dispersed, or those previously dissolved in oil-in-water emulsions may be added to the starchy raw materials.

  Processing is done by adding acid-soluble soy protein to starchy raw materials, and then heating or baking a water-based dough, without fermenting or fermenting, and making it the final food. . It can also undergo freezing or refrigeration after the dough or heating.

  Examples of the present invention are shown below, but the technical scope of the present invention is not limited by these examples. Unless otherwise specified, “%” means “% by weight” and “part” means “part by weight”.

<Production Example 1>
35 kg of water is added to 5 kg of low-denatured defatted soybean (nitrogen soluble index (NSI): 91) obtained by compressing soybean and extracting and removing oil using n-hexane as an extraction solvent. The solution was adjusted to pH 7 and extracted while stirring at room temperature for 1 hour, followed by centrifugation at 4,000 G to separate okara and insoluble matter to obtain skim soymilk. The defatted soymilk is adjusted to pH 4.5 with phosphoric acid and then centrifuged at 2,000 G using a continuous centrifuge (decanter) to obtain an insoluble fraction (acid precipitation card) and a soluble fraction (whey). It was. The acid precipitation card | curd was watered so that it might become 10 weight% of solid content, and the acid precipitation card | curd slurry was obtained. This was adjusted to pH 3.5 with phosphoric acid and then heated at 120 ° C. for 15 seconds in a continuous direct heat sterilizer. This was spray-dried to obtain an acid-soluble soybean protein powder (hereinafter abbreviated as S). The dissolution rate of this protein was 61% at pH 4.0.

<Production Example 2>
The acid precipitation curd slurry obtained in the same manner as in Production Example 1 was adjusted to pH 4.0 with phosphoric acid and then heated to 40 ° C. To this solution, 8 units of phytase (manufactured by NOVO) per solid content was added, and the enzyme action was performed for 30 minutes. After the reaction, the solution was adjusted to pH 3.5 and heated at 120 ° C. for 15 seconds with a continuous direct heating sterilizer. This was spray-dried to obtain 1.5 kg of acid-soluble soybean protein powder (hereinafter abbreviated as T). The dissolution rate of this protein was 95% at pH 4.0.

Examples 1 to 6: Manufacture of sponge cake 150 parts of whole egg, 110 parts of super white sugar, emulsified oil (made by Fuji Oil Co., Ltd.) 20 parts "Perming H", sorbitol preparation (made by Towa Kasei Kogyo Co., Ltd.) "Foodle 70 10 parts of water and 0-5 parts of water are mixed at a low speed with a Kenwood mixer (manufactured by Aiko Co., Ltd.) and a stirring blade whip for 30 seconds at a room temperature of 25 ° C., and further, soft flour (manufactured by Nippon Flour Mills Co., Ltd.) “Violet” 95-99. 9 parts, baking powder (manufactured by Aikoku Sangyo Co., Ltd.) 1 part “baking powder red can”, 0.1-5 parts of acid-soluble soybean protein powder T obtained in Production Example 2 above with a whip at low speed for 30 seconds By mixing, a pasty dough was obtained. The paste dough was mixed at high speed for 3 minutes and 30 seconds using a stirring blade whipper to obtain the whipped dough of Examples 1 to 6 having a dough specific gravity of 0.43 (see Table 1 for the number of parts to be changed). Furthermore, these whipped doughs were put into a baking mold having an internal volume of 1500 cc for No. 6 size cake deco and baked for 35 minutes in an electric oven PRINCEII manufactured by Fujisawa Seisakusho adjusted to 170 ° C. Table 2 summarizes the results.

Examples 7-8
In Example 1, in place of the acid-soluble soybean protein, 1 to 0.5 parts of the acid-soluble soybean protein powder S obtained in Production Example 1 above, and the other paste states in the same manner according to the formulation in Table 1 The dough was obtained and fired in the same manner.

Comparative Examples 1-3
In Examples 1 to 6, instead of acidic soluble soy protein, commercially available soymilk powder (manufactured by Fuji Oil Co., Ltd.) “0-10 parts of Soyafit 2000 (soy protein content 62.8% weight / dry The product was obtained in the same manner except that it was used as a product, 20% at a protein dissolution rate of pH 4.0).

  The cross-sectional area index in Table 2 was measured by the following method. That is, a cake knife is used to divide the fired sponge cake from the top surface to the bottom surface, and the left and right portions are equally divided into two, and one of the left and right is used as a measurement sample. Copy the cross section of the sample with a copier (Fuji Xerox Co., Ltd.) “DocuCenter Color a450”, cut out the portion where the cross-sectional area of the copied paper is shown, measure the weight, and copy the area / weight ratio of the paper The area cm2 of the part reflected from the above was calculated. The cross-sectional area of Comparative Example 1 was fixed at 100, and the areas of Comparative Examples 2 and 3 and Examples 1 to 8 were expressed as indexes, and those with large index values had good volume.

  The evaluation of the inner layer state of the fired product in Table 2 was performed as follows. Ten panelists evaluated the state of the inner layer of the cross section of the sample used for the measurement of the cross-sectional area index by five points, and used the average point. The inner layer is porous and has a uniform bubble structure, with 5 points for the handmade and good inner layer, 3 points for the weak inner layer with obscure features, and 1 point for the defective inner layer that is too rough due to the mixing of large and small bubbles. did.

Evaluation of the texture of the baked product in Table 2 was performed as follows. Five panelists sampled the state of the inner layer of the sample used for the measurement of the cross-sectional area index, evaluated 10 points, and used the average score. It has a moderate elasticity and crispness, and has a good texture with a good throat, 5 points, and 3 points with a weak texture that has a characteristic of being spoiled. Points.
Comparative Examples 2 to 3 in which 5.26% to 11.1% of the adjusted soymilk powder, which is a kind of soybean protein product, is used for the soft flour, the inner layer and the texture compared to Comparative Example 1 in which no soy protein product is used. However, there was a drawback that the volume of the sponge cake was reduced, and a large amount of adjusted soymilk powder was necessary to exert the effect.

  The sponge cake using the acid-soluble soybean protein of Examples 1 to 8 had a handmade characteristic inner layer and good texture, and was a good overall quality result. Furthermore, the modified soymilk powder exhibited an effect at a low level of use, and there was no decrease in volume, and a differentiated effect from the conventional soybean protein product was observed. In particular, the acidic soluble soybean protein powder T showed a more preferable inner layer state and texture compared to the powder S.

Examples 9 to 11: Production of butter cake 120 parts of white sucrose, 5 parts of shortening (Fuji Oil Co., Ltd.) “Pampas LB”, 5 parts of emulsified fat (Fuji Oil Co., Ltd.) “Perming H”, salt 2 Parts at room temperature of 25 ° C. with a Kenwood mixer (manufactured by Aiko Co., Ltd.) and mixing with a stirring blade beater at low speed for 30 seconds. Further, 97 to 100 parts of soft flour (manufactured by Nippon Flour Mills) “Violet”, 5 parts of corn starch, baking powder ( Made by Aikoku Sangyo Co., Ltd.) "Baking powder red can" 3 parts, acid soluble soy protein powder T 0.5-3 parts beaten and mixed for 30 seconds at low speed, then 85 parts whole egg (net), 60 parts water ~ 63 parts, 60 parts of salad oil (manufactured by Fuji Oil Co., Ltd.) “rapeseed salad oil” were added in order and mixed for 2 minutes at a low speed of beater to obtain a uniform paste-like butter cake dough, and these Put 150g pasty dough into rectangular butter cake baking mold size 130 mm × 56 mm × height 15 mm, the fired results of these are summarized in Table 4 for 30 minutes at adjusted Fujisawa Seisakusho electric oven PRINCEII to 160 ° C..

Comparative Example 4
A dough was prepared and baked by the same manufacturing method as in Example 9 except that acid-soluble soybean protein was not used.

  The inner layer state and texture of the baked product were evaluated by a 10-point method using 10 panelists, and the results are summarized in Table 4.

  As shown in the results of Table 4, Examples 9 to 11 to which acidic soluble soybean protein was added showed a great texture improvement effect as compared with Comparative Example 4.

Examples 12-14: Manufacture of donuts Soft flour (Nippon Flour Mills) "Violet" 97-99.5 parts, Acid-soluble soybean protein powder T 0.5-3 parts, Super white sugar 33.8 parts, Salt 1 .5 parts, baking powder (manufactured by Aikoku Sangyo Co., Ltd.) 3 parts of “baking powder red can” and 3 parts of skimmed milk powder are mixed at a low temperature for 30 seconds with a Kenwood mixer (manufactured by Aiko Co., Ltd.) and a stirring blade beater. Further, 15 parts of whole egg (net), 52 to 55 parts of water, 60 parts of vegetable margarine (Fuji Oil Co., Ltd.) “Pariol 500” are dissolved in a hot water bath and added in order, and mixed at a beater low speed for 2 minutes. A uniform pasty donut dough was obtained and summarized in Table 5 of Examples 12-14. Put pasty dough into donut dough squeezer (Kanto Shoji Co., Ltd.) “Aluminum donut maker” and heat it to 180 ° C in a fryer (Mach Equipment Co., Ltd.) “Electric fryer”. Fry for a total of 4 minutes.

Comparative Example 5
A pasty dough as shown in Table 5 was obtained with substantially the same formulation as in Example 14 except that acid-soluble soybean protein was not used, and fried under the same conditions.

  The inner layer state and texture of the fried product were evaluated by a 10-point method using 10 panelists, and the results are summarized in Table 6.

  As shown in Table 6, Examples 12 to 14 to which acidic soluble soybean protein was added showed a significant texture improvement effect as compared with Comparative Example 5.

Example 15: Manufacture of shoe puff Shoe puff dedicated margarine (manufactured by Fuji Oil Co., Ltd.) “Shoe Top D” 130 parts and water 120 parts were weighed into a container of Kenwood mixer (manufactured by Aiko Co., Ltd.), and heated and boiled with gas fire Let In a mixture of boiled margarine and water, add 79 parts of "Violet" soft flour (Nippon Flour Mills), 20 parts of "Eagle" strong flour (Nippon Flour Mills), 1 part of acid soluble soy protein powder T, feather Mix in a beater at medium speed for 3 minutes to evenly mix and hydrate the protein, starch, boiled margarine and water mixture contained in the powder. 200 parts of whole egg (net), 1 part of ammonium hydrogen carbonate (expansion agent) "Happo Shokai Co., Ltd.", 0.5 parts of sodium hydrogen carbonate (expansion agent) "Happo Shokai Co., Ltd." To do. Add 1/3 of the egg and leavening agent mixture to the mixture of powder, boiled margarine and water and mix with a feather beater at medium speed for 2 minutes, then add 1/3 of the mixture at medium speed to 2 Mixing was completed, and finally one third of the remaining mixture was added and mixed at medium speed for 2 minutes to obtain a pasty shoe puff dough. The paste-like shoe puff dough was put in a bag and baked for 16 minutes in an electric oven PRINCE II manufactured by Fujisawa Seisakusho, which was squeezed spherically with 20 g on an iron plate and adjusted to 200 ° C.

Comparative Example 6
A dough was prepared by substantially the same production method as in Example 15 except that the acid-soluble soybean protein was not used.

  The inner layer state and texture of the baked product were evaluated by a 10-point method using 10 panelists, and the results are summarized in Table 8.

  As shown in the results of Table 8, Example 15 to which acidic soluble soybean protein was added showed a great texture improvement effect as compared with Comparative Example 6.

Example 16 and Comparative Example 7: Production of Cookies Cookies were produced by the usual method with the composition shown in the table below.

  A desktop vertical mixer was used for the cookie prototype, and a beater was attached to the attachment. First, the above blend was mixed at low speed with the target of a specific gravity of 0.85, and the whole egg was added in 4 or 5 portions. Further, with stirring, charcoal dissolved in water was added, and then Western liquor was sequentially added and mixed. Stop stirring, add weak flour all at once, stir at the lowest speed, stop stirring when the powder is sprinkled all over, mix gently by hand, keep this dough tightly, store in a refrigerator overnight It was. The next day, the fabric (product temperature 6-7 ℃) is put on a sheeter with a gauge thickness of 6mm, stretched to a fabric thickness of 6.2mm, and die-cut (about 11.5g / sheet) with a diameter of 45mm. Bake at 9 ° C. for 9 minutes. In the examples, there was no problem in workability such as preparation of dough, and dough sagging during firing did not occur.

  While the cookie of Comparative Example 7 was slow to loose and chewed tightly, the cookie of Example 16 had characteristics of moderate crunch and good looseness.

Examples 17 to 19 and Comparative Example 8: Manufacture of croquette Add "Cook croquette" (elementary ingredient of croquette) made by Nippon Shokuken Co., Ltd. to twice the weight of warm water, and make it uniform. The mixed and cooled medium-sized dough of croquette was molded to 45 g using a drum type molding machine (manufactured by Nippon Carrier Kogyo Co., Ltd.). One medium seed was fast-frozen with 15 g of batter and 15 g of bread crumbs, and then fried at 175 ° C. for 5 minutes. The batter was prepared by pre-mixing necessary powder materials in 5 ° C. cold water. The composition of the batter is shown in Table 10.

  A frozen croquette that was allowed to stand at room temperature for 7 hours was evaluated by sensory evaluation. The evaluation results are shown in Table 11. The texture was evaluated by 10 panelists in the order of 5 to 1 in the order of 5 points, and expressed as an average score.

  By adding the acid-soluble soybean protein powder T, a crumpled feeling and a crispy feeling were imparted, which was better than the comparative example. However, as the amount added increased, the hardness of the bite was bothering and the function improvement effect tended to be weakened. Overall, the 1% addition group had a good texture balance. Moreover, what passed 4 hours and 7 hours after frying was evaluated. In the example to which the acid-soluble soybean protein was added, there was little sag of clothing over time, and the texture was better than in the comparative example.

Examples 20-21 and comparative example 9: manufacture of kakiage

  According to the composition of Table 12 and Table 13, the flour was added to the vegetables and mixed, and then the dressing liquid was added and further mixed. (Each meal was carried out manually.) The dough was put in a frying cup for making kakiage, fried at 165 ° C. for 1 minute 30 seconds, and quickly frozen. When cooking, the food texture was evaluated by re-frying at 170 ° C. × 1 minute 15 seconds.

  The sensory evaluation was made after 2 hours from frying. The evaluation results are shown in Table 14. The texture was evaluated by 10 panelists in the order of 5 to 1 in the order of 5 points, and expressed as an average score.

  By adding the acid-soluble soybean protein, a soft and crispy sensation was given to the clothing, and there was little sag of the clothing over time, which was better than the comparative example. However, as the added amount increases, the hardness of the bite becomes worrisome, and overall, the 1% added section has a good texture balance.

Example 22 and Comparative Example 10: Bread Production Bread was produced by a conventional method with the composition shown in the table below.

  The workability of Example 22 in which the acidic soluble soybean protein powder T was blended was somewhat harsh at the beginning of mixing compared to the unblended Comparative Example 10, but it was almost the same as the control at the time of kneading. The workability was almost the same. As a result of measurement by exotensograph, the physical properties of the fabric were the same in terms of tensile strength, elongation, and shape factor, and it was shown that the fabric properties were almost the same (Table 17). Further, the appearance after firing was the same in volume, and the appearance of the inner layer was not significantly different in color tone, eye roughness, shape and the like. The pan specific volume was also almost the same as the comparative example (Table 18).

  Although the dough physical properties and bread volume were the same, Example 22 was superior to Comparative Example 10 in terms of bread texture. That is, in the raw state without toast, it was difficult to form a dango shape in the mouth and the mouth melted well. When toasted, it was modified to a light and crunchy texture, which was preferable.

Example 23: Manufacture of non-fried noodles Salts (30 parts of salt, 3 parts of potassium carbonate, 3 parts of sodium carbonate) were added to 680 parts of water at room temperature while stirring, and the mixture was stirred and dissolved for 10 minutes (preparation of a water adjustment liquid) ). Wheat flour (made by Nisshin Seifun Co., Ltd.) “Hiryu” 1800 parts, tapioca starch (manufactured by Nissho Chemical Co., Ltd.) “Z-100” 200 parts, acid-soluble soybean protein powder T 20 parts obtained in Production Example 2 The powder was mixed and passed through 200 mesh. The powder mixture was put into a coat mixer, and the hydration adjusting solution was added in 5 minutes while stirring at low speed, and added in 2 minutes, followed by low speed stirring for 7 minutes and medium speed stirring for 8 minutes. The okara-shaped dough (pH 8.5) was transferred to a noodle making machine, combined (adjusted to a thickness of 2.7 mm), and made into a noodle band. Further, rolling was repeated and finally the thickness was adjusted to 0.7 mm. The noodle strip was cut to an appropriate size, and the noodle strings were steamed with a steamer for 6 minutes. The steamed noodle strings were dried with a hot air dryer at 85 ° C. for 60 minutes, and after drying, the noodles were allowed to cool to room temperature.

Comparative Example 11
In Example 23, it was prepared in the same manner except that the acid-soluble soybean protein powder T was not added.

Comparative Example 12
In Example 23, instead of 20 parts of acidic soluble soybean protein powder T, separated soybean protein (Fuji Oil Co., Ltd.) “Fujipro F (protein dissolution rate: pH 4.0, 10%)” 20 Prepared in the same manner as in Example 23, except that parts were used.

  As shown in Table 20, with respect to the state during the work process, the noodle band was harder to the comparative example 11 than the comparative example 12, but in Example 23, it was softer and more flexible to the comparative example 11 on the contrary. Yes, apparently the soy protein isolate increased in dough viscosity, whereas the acid-soluble soy protein did not increase in dough viscosity, but decreased moderately.

  The noodle evaluation method was carried out by putting noodles into a cup, pouring boiling water, and eating the noodles after returning to hot water by a sensory test with 10 panelists. As a result of looking at the texture after returning to the hot water, Comparative Example 11 was powdery, easy to break, and sticky, and Comparative Example 12 felt that the noodles were hard and easily cut off. No. 23 had little powderiness and stickiness, and it was preferable to feel moderate elasticity and suppleness when biting.

In the case of instant dry foods, there are specific problems such as rejuvenation, stretch, and loosening, and these points were evaluated.
“Return to hot water”: Restoration after 3 minutes, 5 minutes, and 7 minutes after hot water return showed that Comparative Examples 11 and 12 had a hard core remaining after 5 minutes, and the restoration was completed after 7 minutes. On the other hand, in Example 23, restoration was almost completed after 5 minutes, and there was a tendency for hot water to return quickly.
“Hot water elongation”: When the texture after 10 minutes of hot water return was observed, Comparative Examples 11 and 12 were soft and increased in stickiness, and apparently hot water was stretched, whereas Example 23 was softer. A moderate hardness was maintained, and there was a tendency for hot water to stretch.
“Feeling”: When the loosening properties of the noodles after 3 minutes after returning to the hot water were observed, Comparative Examples 11 and 12 showed that the noodles were not easily loosened, while Example 23 was clearly loosened with little entanglement. The tendency was easy.

  From the above results, it was found that the effects of instant dry foods such as hot water return, hot water stretch, and loosening were also recognized.

  In addition, instead of the acid-soluble soybean protein powder T of Example 23, the acid-soluble soybean protein powder S obtained in Production Example 1 is used. As a result, Example 23 was superior in the supple texture. As described above, it was found that the effect of improving the noodle quality of non-fried noodles can be obtained by adding acidic soluble soybean protein.

Examples 24-26: Manufacture of udon 4 parts of salt was added to 40 parts of water at room temperature while stirring, and the mixture was stirred and dissolved for 10 minutes. (Preparation of water adjustment liquid). 100 parts of neutral powder for udon (manufactured by Nitto Flour Mills Co., Ltd.) is sufficiently mixed with acid-soluble soybean protein powder T (0.5 part, 1.0 part, 1.5 part) and passed through 200 mesh. It was. Add the powder mixture to the coat mixer, add the hydration adjustment solution in 5 minutes while stirring at low speed, add it over 2 minutes, scrape off 5 minutes after starting the stirring, and further 5 minutes (10 minutes in total) Stirring was performed. The dough that was in the shape of a rag was transferred to a noodle making machine and combined (thickness 5.0 mm) to form a noodle strip. The noodle strip was repeatedly rolled three times to obtain a noodle strip having a final thickness of 2.0 mm. The noodle strip was cut into a width of 3 mm with a noodle cutter to obtain raw udon.

  After standing still in the refrigerator overnight, 10 times the amount of boiling water was prepared for the raw noodles, and the raw noodles were added and heated for 10 minutes to obtain udon.

Comparative Example 13
It was prepared in the same manner as in Example 24 except that acid-soluble soybean protein powder was not added.

  The evaluation method was a sensory evaluation method by 10 panelists regarding “texture” immediately after boiled and “boiled stretch” in a state soaked in warm soup. Examination of the “texture” immediately after boiling, in Comparative Example 13, the hardness of the udon is weak and there is not much elasticity and stiffness, whereas in Examples 24-26, the hardness to the udon, elasticity of the noodles, and stiffness are imparted It was confirmed that the texture was favorable. In the addition amount of acid-soluble soybean protein, 1.0 part was most preferable in terms of imparting the hardness of udon, elasticity of noodles, and stiffness, followed by addition of 1,5 parts and then addition of 0.5 parts.

  In “boiled and stretched”, the soup adjusted to 80 ° C. was soaked with udon immediately after boiling, and after 5 minutes and 10 minutes, the comparative example showed that the udon was soft and slightly stretched after 5 minutes. In contrast, in the examples, the texture immediately after being boiled was maintained. In the state after 10 minutes, the comparative example was in a state where the growth of the udon progressed with the cocoon and the udon was soft and less stiff, whereas in the example, the hardness which is not in the comparative example despite the slight extension of the cocoon, It was confirmed that there was elasticity and stiffness.

  As described above, it was found that the effect of improving the noodle quality on udon can be obtained by adding oxidized soluble soybean protein.

Example 27: Flour paste Using the acid-soluble soybean protein powder T obtained in Production Example 2, a flour paste was prepared. Frozen egg yolk “Gold York” (manufactured by Kewpie) 4.0 parts, lactoglobulin “Sunlacto N5” (manufactured by Taiyo Kagaku) 2.0 parts, skim milk powder 4.0 parts, dextrin 10.0 parts, water 44.5 Parts, rapeseed oil (produced by Fuji Oil Co., Ltd.) 14.0 parts, granulated sugar 16.0 parts, acid-soluble soybean protein powder 1.0 parts, corn starch “MXPP” (manufactured by Nippon Star Chemical Co., Ltd.) 4.5 parts Was added. Then, it mix | blended for 10 minutes at 60 degreeC. The pH of the mixed solution was 5.9. Furthermore, after homogenizing under a pressure of 100 kg / cm 2, it was heated to 100 ° C. by a method of indirect heat treatment with a kneader, and the starch was gelatinized to form a paste. Immediately after removal from the kneader, it was a solid shape-retaining material. The flavor of the flour paste after cooling in the refrigerator (5 ° C.) was good, the texture was smooth and the mouthfeel was good.

Comparative Example 14
A flour paste was prepared in the same manner as in Example 27 except that acid-soluble soy protein was not added. Immediately after removal from the kneader, it was a solid shape-retaining material. The flavor of the flour paste after cooling in the refrigerator (5 ° C.) was good, but the texture was unfavorable because the starch had a strong paste and was very heavy in the mouth.

Example 28: Acidic flour paste An acidic flour paste was prepared using the acidic soluble soybean protein powder T obtained in Production Example 2 above. 20 parts of commercially available 100% orange juice, 35.5 parts of water, 14 parts of rapeseed oil (manufactured by Fuji Oil Co., Ltd.), 23 parts of granulated sugar, 3 parts of acid-soluble soybean protein powder T, corn starch “MXPP” (Nissho Chemical Co., Ltd.) 4.5 parts) was added. Then, it mix | blended for 10 minutes at 60 degreeC. The pH of the mixed solution was 3.8. Furthermore, after homogenizing under a pressure of 100 kg / cm 2, the starch was heated to 85 ° C. by a method of indirect heat treatment with a kneader, and starch was gelatinized to form a paste. Immediately after removal from the kneader, it was a solid shape-retaining material. The texture of the flour paste after cooling in the refrigerator (5 ° C.) was firm and the mouthfeel was good. Also, the orange flavor was clear and finished in a natural taste.

Example 29
A flour paste was obtained in the same manner as in Example 28 except that the acid-soluble soybean protein powder T was 2 parts and the water content was 36.5 parts. This was slightly weaker in shape retention than the flour paste of Example 28, but had a firm texture. The mouthfeel was good as in Example 28. Regarding the flavor, as in Example 28, the flavor of natural fruit juice was felt.

Comparative Example 15
In Example 28, the whole amount of acidic soluble soy protein was replaced with whey protein “Sanlacto N5” (manufactured by Taiyo Kagaku Co.). The pH of the mixture was adjusted to 3.8 with lactic acid. The others were carried out according to Example 28. Thus, the obtained flower paste had no shape retention like that obtained in Example 28, and it flowed when tilted, and was a liquid that would sag when squeezed with a mold. The orange flavor was mixed with the milk flavor and was blurred, making it hard to feel the orange flavor. Further, compared to Example 28, the acidity was felt very strongly, which was not preferable.

Comparative Example 15
In Comparative Example 15, the amount of corn starch used was 7.5 parts, granulated sugar was 20 parts, and the pH of the mixture was adjusted to 3.8 with lactic acid. The others were carried out according to Example 28. The obtained paste had a shape retaining property as compared with Comparative Example 15, but had a shape retaining property derived from starch, had a poor throat passage, had a pasty feel, and was not textured as in Example 29. It was.

  Table 23 shows the composition and evaluation of the flour pastes of Examples 28 to 29 and Comparative Examples 15 to 16.

Example 30
An acidic flour paste was prepared using the acidic soluble soybean protein obtained in Production Example 2 above. Passion fruit concentrated turbid juice (sugar content 50.5 °, acidity 13.90%, Tokyo Food Techno Co., Ltd.) 10 parts, water 45.5 parts, rapeseed oil (Fuji Oil Co., Ltd.) 14 parts, granulated sugar 23 parts, acidic 3 parts of soluble soybean protein powder T and 4.5 parts of corn starch “MXPP” (manufactured by Nissho Chemical Co., Ltd.) were added. Then, it mix | blended for 10 minutes at 60 degreeC. The pH of the mixed solution was 3.5. Furthermore, after homogenizing under a pressure of 100 kg / cm 2, the starch was heated to 85 ° C. by a method of indirect heat treatment with a kneader, and starch was gelatinized to form a paste. Even immediately after taking out from the kneader, it was a solid shape-retaining material. The texture of the flour paste after cooling in the refrigerator (5 ° C.) was firm and the mouthfeel was good. In addition, the flavor of passion fruit was clear and finished in a natural taste.

Example 31: Production of acidic cream containing acidic soluble soybean protein T2 part of acidic soluble soybean protein, sucrose fatty acid ester (manufactured by Mitsubishi Chemical Foods) "Ryoto Sugar Ester S-570" 0.2 Part of the mixture is mixed with powder and added to and dissolved in 52.8 parts of water to prepare an aqueous phase. 45 parts of salad oil is added, the oil phase and aqueous phase are stirred with a homomixer at 70 ° C for 15 minutes and pre-emulsified, then homogenized at a homogenization pressure of 1 MPa, and directly heated at 144 ° C for 4 seconds using an ultra-high temperature sterilizer. After performing the sterilization treatment by the above, the mixture was homogenized at a homogenization pressure of 4 MPa and immediately cooled to 5 ° C. After cooling, the mixture was aged for about 24 hours to obtain an acidic cream (pH 3.5).

  25 parts of acidic cream blended with the above-mentioned acidic soluble soybean protein was added to 100 parts of Comparative Example 1 to produce a sponge cake. The obtained sponge cake had the same handmade inner layer and good texture as in Examples 1-8. In this way, the acid-soluble soybean protein can be obtained in the same manner by previously preparing an oil-in-water cream and then adding it, so that the acid-soluble soybean protein is blended and used as a sponge cake kneading cream It is also possible.

Example 32: Production of shortening blended with acid-soluble soybean protein Acid-soluble soybean protein T16.7 parts was added to 83.3 parts of "Pampas LB" shortening (manufactured by Fuji Oil Co., Ltd.). Then, kneading was carried out with stirring to produce a shortening blended with acid-soluble soybean protein. Bread was produced in the same manner as in Example 22 except that 6 parts of the shortening blended with the above acidic soluble soybean protein was used in place of 1 part of the acid soluble soybean protein of Example 22 and 5 parts of Pampas LB.

  As a result, the workability, the physical properties of the dough, the appearance after firing, the specific volume, and the texture are almost the same as in Example 22, and the acid-soluble soybean protein is kneaded into the shortening in advance. It has been shown that it can be used as a shortening.

Claims (4)

A flour paste obtained by adding acidic soluble soybean protein to starchy raw materials. The flour paste according to claim 1, wherein the starch-based raw material is mainly composed of starch-based flour, starch obtained from the starch, processed starch, or a mixture thereof. The flour paste according to claim 1, wherein the acid-soluble soybean protein is 50% by weight or less based on the starchy raw material. The flour paste according to claim 1, wherein the flour paste has a pH of 3.5 to 5.9.